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Study on the Adhesion Force Between Ga-Doped ZnO Thin Films and Polymer Substrates
摘要: Flexible Ga doped ZnO (GZO) transparent conductive thin films were prepared on polycarbonate (PC) substrates at room temperature by magnetron sputtering. The adhesive property between the GZO film and the PC substrate was investigated quantitatively by the scratch test, which is designed for the quantitative assessment of the mechanical integrity of coated surfaces. The effect of the sputtering pressures on the adhesion forces for the GZO films was investigated. When the sputtering pressure varied from 0.2 to 0.5 Pa, no obvious adhesion force alteration was observed. However, when the sputtering pressure was increased to 0.7 Pa, the adhesion force was decreased. The lowest square resistance of the GZO film was 18.6 Ω/sq. Regardless of the sputtering pressure, the transmittance in the visible light was about 90%. When the sputtering pressure was 0.4 Pa, the optimal figure of merit (ΦTC) was 2.5 × 10?2 Ω?1, indicating that the optimal pressure was 0.4 Pa.
关键词: Adhesion Force,Flexibility,ZnO Transparent Conductive Film
更新于2025-09-23 15:23:52
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Rationally Designed Nanostructure Features on Superhydrophobic Surfaces for Enhancing Self-Propelling Dynamics of Condensed Droplets
摘要: Self-propelling ability towards achieving more efficient dropwise condensation intensively appeals to researchers due to its academic significance to explain some basic wetting phenomena. Herein we designed and fabricated the two types of microstructure superhydrophobic surfaces, i.e., sealed layered nanoporous structures (SLP-surface) and open nanocone structures (OC-surface). As a consequence, the resultant surfaces exhibit the robust water repellency, and the water droplet nearly suspends on the superhydrophobic surfaces (CA=158.8°±0.5°, SA=4°±0.5° for SLP-surface and CA=160.2°±0.4°, SA=1°±0.5° for OC-surface, respectively). Meanwhile, the impacting droplets can be rapidly rebounded off with shorter contact time of 11.2 ms and 10.4 ms (impact velocity V0 = 1 m/s). The excellent static-dynamic superhydrophobicity is mainly attributed to the air pockets captured by the both microscopic rough structures. Regarding the self-propelling ability of condensed droplets, it is found that the droplet microscopic pining effect of SLP-surface severely weakens dynamic self-propelling ability of condensed droplets. The capillary adhesive force induced by the sealed layered nanoporous structures is up to 16.0 μN. However, the open nanocone structures cause lower water adhesive force (~4.1 μN) under the action of flowing air pockets, producing higher dynamic self-propelling ability of condensed droplets. As a consequence, the open nanocone structure superhydrophobic surface displays a huge potential of inhibiting attachment of condensed droplets.
关键词: self-propelling ability,superhydrophobic,water adhesion force,designed nanostructures
更新于2025-09-23 15:23:52
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Atomic Force Microscopy in Molecular and Cell Biology || AFM Imaging-Force Spectroscopy Combination for Molecular Recognition at the Single-Cell Level
摘要: Molecular recognition at the single-cell level is an increasingly important issue in Biomedical Sciences. With atomic force microscopy, cell surface receptors may be recognized through the interaction with their ligands, inclusively for the identification of cell-cell adhesion proteins. The spatial location of a specific interaction can be determined by adhesion force mapping, which combines topographic images with local force spectroscopy measurements. Another valuable possibility is to simultaneously record topographic and recognition images (TREC imaging) of cells, enabling the mapping of specific binding events on cells in real time. This review is focused on recent developments on these molecular recognition approaches, presenting examples of different biological and biomedical applications.
关键词: Molecular recognition,TREC imaging,Atomic force microscopy,Adhesion force mapping,Biomedical applications
更新于2025-09-23 15:21:01
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Adhesion Behavior between Multilayer Graphene and Semiconductor Substrates
摘要: A high bonding strength between graphene and a semiconductor surface is significant to the performance of graphene-based Micro-Electro Mechanical Systems/Nano-Electro Mechanical Systems (MEMS/NEMS) devices. In this paper, by applying a series of constant vertical upward velocities (Vup) to the topmost layer of graphene, the exfoliation processes of multilayer graphene (one to ten layers) from an Si semiconductor substrate were simulated using the molecular dynamics method, and the bonding strength was calculated. The critical exfoliation velocities, adhesion forces, and adhesion energies to exfoliate graphene were obtained. In a system where the number of graphene layers is two or three, there are two critical exfoliation velocities. Graphene cannot be exfoliated when the Vup is lower than the first critical velocity, although the total number of graphene layers can be exfoliated when the Vup is in the range between the first critical velocity and second critical velocity. Only the topmost layer can be exfoliated to be free from the Si surface if the applied Vup is greater than the second critical velocity. In systems where the number of graphene layers is four to ten, only the topmost layer can be free and exfoliated if the exfoliation velocity is greater than the critical velocity. It was found that a relatively low applied Vup resulted in entire graphene layers peeling off from the substrate. The adhesion forces of one-layer to ten-layer graphene systems were in the range of 25.04 nN–74.75 nN, and the adhesion energy levels were in the range of 73.5 mJ/m2–188.45 mJ/m2. These values are consistent with previous experimental results, indicating a reliable bond strength between graphene and Si semiconductor surfaces.
关键词: adhesion force,bonding mechanism,adhesion energy,exfoliation behavior,MEMS/NEMS,molecular dynamics,graphene
更新于2025-09-23 15:19:57
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[IEEE 2018 International Semiconductor Conference (CAS) - Sinaia (2018.10.10-2018.10.12)] 2018 International Semiconductor Conference (CAS) - Effect of the Deposition Conditions on Titanium Oxide Thin Films Properties
摘要: This paper presents the fabrication and characterization of titanium oxide thin films deposited by Pulsed Laser Deposition in different experimental conditions. The scope of this work is to investigate the effect of the oxygen pressure in the deposition chamber on the material properties. Thin films characterizations include the mechanical and tribological properties such as the modulus of elasticity, hardness and the adhesion force. The mechanical and tribological properties of the materials are experimentally determined by using the atomic force microscopy technique. The effect of the oxygen pressure on the film thickness is analyzed. As the pressure in the deposition process decreases, the thickness of the thin films increases, respectively. The surfaces roughness increases as the deposition pressure decreases that leads to a decrease of adhesion forces. Hardness and modulus of elasticity increases as the deposition pressure decreases. This study shows that the mechanical and tribological properties of the investigated thin films strongly depend on the grain size and the films density, which are influenced by the deposition conditions (the oxygen pressure in the deposition chamber).
关键词: pulsed laser deposition,thin films,adhesion force,hardness,modulus of elasticity
更新于2025-09-19 17:15:36
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Control of adhesion force for micro LED transfer using a magnetorheological elastomer
摘要: Liquid crystal display and organic light emitting diode (LED) account for most of the display market. Globally, micro LED has gained wide attention. A microchip must be moved on the substrate correctly to mass-produce micro LED displays. The original method of moving microchips uses a polymer stamp to control adhesion, such as changing contact force and separation velocity. However, this method causes the problem of repeatability. In this study, a stamp is produced based on biomaterial engineering that controls the characteristic of the material surface using microstructures. The magnetorheological elastomer is used, which can control mechanical properties according to the magnetic field. Furthermore, the possibility of the pick and place process for microchips is analyzed.
关键词: Adhesion force,MRE (magnetorheological elastomer),Photolithography,Micro-structure
更新于2025-09-12 10:27:22